The work of Steidel and collaborators (e.g.
Steidel et al. 1996)
has confirmed a substantial population of star-forming galaxies at z
around 3,
with a comoving number density of roughly 10 to 50% that of present
day luminous (LL)
galaxies. From these data it has been possible to
sketch - although with large uncertainties and questions - the
star-forming history of the Universe at high redshifts
(Madau et al. 1996).
From this work,
and other similar samples, e.g. from the HDF, the overall SFR of the
galaxy population seems to
increase from z = 0 to z = 2, during which time a
significant fraction of the heavy
elements in the Universe are formed, while it tails off again towards
higher redshift. Recently,
Steidel et al. (1999)
questioned the decrease in the number of
star forming galaxies at high redshift, and suggest that the cosmic star
formation
rate as inferred from Lyman break galaxies has been constant from
z = 1 to z = 4.
Recent results from sub-mm observations of redshifted dust emission with
the SCUBA bolometer array (e.g.
Hughes et al. 1998)
and from the ISO satellite
(Aussel et al. 1999;
Puget and Guiderdoni
1999)
suggest that a significant amount of
high redshift star formation may be dust obscured, meaning that
estimates of the cosmic
metal production rate from optical observations might be too low.
The cosmic metal production history may also be constrained by observations
of the extragalactic background at different wavelengths (see
Pagel 1997 for
a discussion).

Numerical simulations by
Cen and Ostriker (1999)
predict the evolution of the
metal content of the Universe as a function of density, by incorporating star
formation and its feedback on the IGM. At a given density (corresponding e.g.
to a rich cluster, a disc galaxy, dwarf etc.) their models predict an
evolution with redshift, but more importantly, the metallicity was found
to be a strong
function of density. At low redshift, low density environments will still be
very metal-poor as suggested by the presence of very metal-poor gas-rich dwarf
galaxies, and Ly absorption
systems
(Shull et al. 1998).
Ferrara and Tolstoy
(1999)
find in their simulations of the feedback from star formation
on the ISM in dwarf galaxies, that low mass galaxies could
be the main contributor to metals in the IGM.

The idea of so-called population III objects has been discussed for
quite a while. These hypothetical objects would be (or host) the first
generation of stars, appearing before the main epoch of galaxy
formation, and thus be a source of pre enrichment in the
Universe. The subject remains speculative, but the existence of Pop III stars
cannot be ruled out
(Cayrel 1996).